Two-photon polymerization of miniaturized 3D scaffolds optimized for studies on glioblastoma multiforme in spaceflight-like microgravity conditions

The obtainment of innovative models recalling complex tumour architectures and activities in vitro is a challenging drive in the understanding of pathology molecular bases, yet it is a crucial path to the identification of targets for advanced oncotherapy. Cell environment recapitulation by 3D scaffolding and gravitational unloading of cell cultures represent powerful means in tumour biomimicry processes, but their simultaneous adoption has consistently been explored only in the latest decade. Here, an unprecedented bioengineering approach capitalizing on spaceflight biology practice is proposed for modelling of glioblastoma multiforme, a highly aggressive neoplasm that affects the central nervous system and has poorly effective pharmacological and radiological countermeasures. Tumour modelling was pursued by the original implementation of two-photon polymerization in fast prototyping of 3D scaffolds on flexible substrates for U87-MG glioma cell culture, and by the exposure of cell-laden scaffolds to simulated microgravity (s-mu g). Realistic spaceflight conditions were applied to collect preliminary information suitable for testing of U87-MG cell-laden scaffold in low Earth orbit. Responses of glioma cells anchored to 3D scaffolds were investigated by microscopy, quantitative reverse transcription-polymerase chain reaction and proteomic analyses, revealing synergic regulatory effects of cell scaffolding and s-mu g on markers of tumour cell growth, metabolism and invasiveness.